WO2014171753A1 - Apparatus and method for forming beam in wireless communication system - Google Patents

Abstract

The present invention proposes an apparatus and a method capable of forming M*N number of beams by a base station, which supports signal transmission/reception of the macro service area in heterogeneous networks in which a macro service area is formed with the M*N number of beams through a two-dimensional arrangement simultaneously considering the horizontal dimension and the vertical dimension and at least one small service is formed in the macro service area. To this end, at least one interference prediction beam formed to transmit signals interfering in transmission signals in at least one small service area from among the signals to be transmitted by the M*N number of beams is selected, and each of the M*N number of beams is formed in consideration of the inter-cell interference in at least one small service area due to the signals to be transmitted by at least one selected interference prediction beam.

Description

Beam shaping device and method in wireless communication system

The present invention relates to an apparatus and method for beam shaping in a wireless communication system having a two-dimensional planar antenna array.

As a core communication technology in the next generation wireless communication system, research on a massive multiple-input multiple-output (MIMO) technology is being conducted. The massive multi-antenna technology supports multi-users based on MIMO technology in base stations using a large number (~ hundreds) of transmit antennas.

In theory, the Transmit Beam Forming Gain is proportional to the number of transmit antennas. Therefore, the large multi-antenna system uses high beam shaping gain, and thus, low transmit power can be used in each transmit antenna, which is emerging as a major technology of green communication.

In particular, as the cells in a wireless communication system become smaller, a study on a large multiple antenna system (hereinafter referred to as a "planar massive MIMO system") using a two-dimensional planar array antenna is being conducted. It is actively underway. According to the planar large multiple antenna system, it is possible to increase the capacity by two-dimensional beam shaping and two-dimensional space division multiple access (SDMA) in the horizontal dimension and the vertical dimension. Do.

The planar giant multiple antenna system supports two-dimensional beamforming. Two-dimensional beamforming by the planar giant multi-antenna system may two-dimensionally subdivide the service area corresponding to the entire cell, and may or may not selectively transmit a signal for each divided area.

Also, as another core communication technology in next-generation wireless communication systems, a lot of researches on Heterogeneous Networks (HetNet) that can increase spectral efficiency have been conducted. As an example of the heterogeneous network, a service area by at least one small eNB in a service area (hereinafter referred to as a "macro service area") by a macro eNB (hereinafter referred to as "small") "Small service area" is overlapping). That is, the small cell corresponding to the at least one small service area overlaps the large cell corresponding to the macro service area.

However, the increase in spectral efficiency in heterogeneous networks is limited by inter-cell interference (ICI) between the macro base station and the small base station. Therefore, in order to increase the spectral efficiency in heterogeneous networks, it is required to develop a technology that effectively avoids ICI.

An embodiment of the present invention discloses an apparatus and method for performing beam shaping so that selective signal transmission is performed for each subregion constituting a service region in order to avoid inter-cell interference in a wireless communication system.

In addition, an embodiment of the present invention discloses an apparatus and method for forming a shadow area for any service area existing in its service area at a base station transmitting a signal by two-dimensional beamforming.

In addition, an embodiment of the present invention discloses an apparatus and method for measuring a state of a downlink by a terminal located in a small service area overlapping a macro service area avoiding inter-cell interference.

In addition, an embodiment of the present invention discloses a data transmitting / receiving apparatus and method for avoiding inter-cell interference by heterogeneous networks in a planar large multi-antenna system and increasing transmission capacity in the heterogeneous networks.

According to an embodiment of the present invention, a macro service area is formed by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension simultaneously, and at least one small service area is formed in the macro service area. The method for shaping the M * N beams by a base station supporting signal transmission / reception in the macro service area in a heterogeneous network may include: the at least one small service area among signals to be transmitted by the M * N beams Selecting at least one interference prediction beam configured to transmit a signal capable of interfering with a transmission signal in U. S., and at least one small service due to the signal to be transmitted by the at least one interference prediction beam selected. Performing beam shaping for each of the M * N beams in consideration of inter-cell interference in a region; The.

In addition, a macro service area is formed by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension simultaneously, and at least one small service area is formed in the macro service area. A base station supporting signal transmission / reception in the macro service area shaping the M * N beams in a heterogeneous network may include: a receiver configured to receive feed-back information from terminals located in the macro service area; At least one configured to transmit a signal that may interfere with a transmission signal in the at least one small service area of the signals to be transmitted by the M * N beams using the feedback information received by a receiver Selecting an interference predicted beam and causing the signal to be transmitted by the selected at least one interference predicted beam A controller which performs beamforming for each of the M * N beams in consideration of inter-cell interference in at least one small service area, and the M * N beams based on the beamforming performed by the controller And a transmitting unit for transmitting the signal.

In addition, a macro service area is formed by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension simultaneously, and at least one small service area is formed in the macro service area. In a heterogeneous network, a method of reporting channel quality information by a UE located in a small service area includes power (S), co-cell interference ( I_intra ), and _inter- cell between the signals received from the small base station serving the small service area. interference (I_ _{inter, NoCoMP)} and the inner inter-cell interference (I_ _{inter, CoMP)} an estimation procedure, and the estimated received signal power (S), the same-cell interference (I_ _intra), external cell interference (I_ _{inter, NoCoMP)} to and the process of configuring the channel quality information using an internal inter-cell interference _{(inter I_, CoMP)} and, included in the process of transferring the small base station the constructed CQI And

In this case _{, it is assumed that the inter-} cell interference ( I_inter _{, CoMP} ) is estimated by an average of interference powers by beams that do not belong to the set of interference beam indexes provided by a macro base station serving the macro service area among the M * N beams. It features.

In addition, a macro service area is formed by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension simultaneously, and at least one small service area is formed in the macro service area. In a heterogeneous network, a terminal located in the small service area that reports channel quality information to the small base station serving the small service area may have a power (S) of a signal received from the base station serving the small service area and the same cell. _{Estimates the} interference ( I_ _intra ), the inter-cell interference ( I_ _{inter, NoCoMP} ) and the inter-cell interference ( I_ _{inter, CoMP} ), and estimates the received signal power (S), same cell interference ( I_ _intra ), and inter-cell interference (I_ _{inter, NoCoMP)} and the inner inter-cell interference _{(inter I_, CoMP)} and a control unit for configuring the channel quality information to use, by the control of the control unit The configured channel quality information includes a transmitter configured to transmit to the small base station,

In this case _{, it is assumed that the inter-} cell interference ( I_inter _{, CoMP} ) is estimated by an average of interference powers by beams that do not belong to the set of interference beam indexes provided by the micro base station serving the macro service area among the M * N beams. It features.

1 is a view showing the structure of a planar giant multiple antenna system based on a heterogeneous network according to an embodiment of the present invention;

2 is a diagram illustrating a procedure for performing resource scheduling for a small service area in a planar giant multi-antenna system based on a heterogeneous network according to an embodiment of the present invention;

3 is a diagram illustrating an example of measuring channel quality of a small service area in a planar giant multi-antenna system based on a heterogeneous network according to an embodiment of the present invention;

4 is a diagram illustrating a signal processing procedure for performing resource scheduling for a small service area in a planar giant multi-antenna system based on a heterogeneous network according to an embodiment of the present invention;

FIG. 5 is a diagram illustrating a control flow performed by a target terminal to configure feedback information and to report it to a macro base station according to an embodiment of the present disclosure; FIG.

FIG. 6 is a diagram illustrating a control flow performed by a target terminal for measuring channel quality of a downlink with a small base station and reporting the small channel quality to the small base station according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described. In this case, names of entities defined for convenience of description may be used in the detailed description. However, the names used for the convenience of description do not limit the rights, it is of course possible to apply by the same or easy changes to the system having a similar technical background.

In addition, in the following detailed description, when it is determined that a detailed description of a known function or configuration may unnecessarily obscure the technical gist of the proposal, the detailed description thereof will be omitted.

In the following description, a method for suppressing interference in a heterogeneous network in which a service area (small service area) by at least one small base station overlaps with a service area (macro service area) by a macro base station is specifically described. It is starting. In the small service area, a terminal having a small base station as a serving base station (hereinafter referred to as a 'target terminal') is used as an interference target to suppress interference due to a signal from a macro base station. And the macro base station is based on the premise that the antennas arranged in the two-dimensional plane to support the service for the terminal located in the macro service area.

The detailed description to be described later allows the macro base station to perform beam shaping for two-dimensional planar arrayed antennas in order to minimize interference at the target terminal due to the signal transmitted by the macro base station. In the beam shaping here, a shadow area in which a small service area is not received by a macro base station transmission signal (downlink physical control channel (PDCCH), downlink physical shared channel (PDSCH), etc.) is not received. Is performed to form.

For example, the macro base station may transmit a signal that will act as an interference to at least one target terminal among beams (hereinafter, referred to as 'two-dimensional pattern beams') divided into horizontal and vertical dimensions by two-dimensional planar arrayed antennas. Block the signal transmission by the beam of (hereinafter referred to as 'interference beam') or perform beam shaping so that the minimum signal is transmitted. For example, among the column vectors of the precoding matrix for beamforming, a column vector corresponding to the interference beam is set to a weight value that prevents a signal from being transmitted in the interference beam.

The macro base station configures a set of interference beam indexes by an index (hereinafter, referred to as an 'interference beam index') for distinguishing at least one interference beam that cannot transmit a signal for each small service area. It may be provided to the target terminal through the base station or directly to the target terminal through the PDCCH.

As another example, the macro base station configures a set of interference weight vector indexes by an index for distinguishing interference weight vectors rather than an interference beam index (hereinafter referred to as an 'interference weight vector index'), and through the small base station of the corresponding small service area. It may be provided to the target terminal or may be directly provided to the target terminal through a PDCCH. The interference weight vector index set is a sum set of interference weight vector indexes which are weighted such that interference beams of a specific target terminal or all target terminals of a two-dimensional pattern beam are blocked. Here, the weight is set so that the interference beam is blocked, which means that the weight is set so that signal transmission is not performed through the beam.

In order for the macro base station to configure an interference beam index set or an interference weight vector index set, a target terminal transmits an index of at least one interference beam or an interference weight vector of the interference beam to the macro base station among two-dimensional pattern beams. You need to report it.

On the other hand, the target terminal receiving the interference beam index set or the interference weight vector index set from the macro base station uses the interference beam index set or the interference weight vector index set provided by the interference beam when measuring the channel state of the downlink. It does not take into account interference due to the received signal. That is, the target terminal may report channel state information (CQI) that avoids interference due to a signal transmitted by the macro base station to the small base station.

Accordingly, the small base station can provide resource scheduling for the target terminal based on the measured CQI by avoiding inter-cell interference. This may be one reason for increasing the transmission capacity in heterogeneous networks by enabling efficient resource scheduling in CoMP.

In the following detailed description, for the sake of convenience, the description will be limited to the example implemented by the interference beam index and the interference beam index set. However, it will be apparent that the details in the detailed description to be described later may be equally applicable to the implementation using the interference weight vector index and the interference weight vector index set.

Meanwhile, in the detailed description to be described below, the macro base station configures the interference beam index set using the interference beam index fed back by the target terminal so that the technical features to be proposed can be supported, and in consideration of the configured interference beam index set The specific operation of determining or constructing a precoding matrix to use for beam shaping will be described in detail.

For example, at least one target terminal located in a small service area by at least one small base station estimates a downlink channel state by two-dimensional pattern beams from the macro base station, and based on this, the beam of the macro base station generating inter-cell interference. To judge. The at least one target terminal feeds back information on the interference beam configured by the at least one interference beam index determined by the determination to the macro base station. Accordingly, the macro base station determines the interference beam index set not to be used for intercell interference avoidance for each small service area by synthesizing the feedback information by the at least one target terminal. However, instead of determining the interference beam index set for each small service area, the interference beam index set may be determined for each target terminal or the entire macro service area. According to only the range of determining the interference beam index set, technical support may be required to propagate the interference beam index set in a different range.

In addition, the operation of the target terminal provided with the interference beam index set by the macro base station to measure the channel quality for the downlink by avoiding the inter-cell interference, and to report it to the small base station will be described in detail.

For example, the macro base station transmits a set of interference beam indexes for each small base station to the target terminal through a downlink signaling channel. Accordingly, the target terminal can measure the CQI for the downlink under the assumption that the macro base station does not use the beam belonging to the interference beam index set.

Lastly, an operation of scheduling a resource for the target terminal in the small service area by the small base station in consideration of CQI, which is channel state information reported from the target terminal, will be described in detail.

DETAILED DESCRIPTION Hereinafter, disclosures required for technical features to be proposed are described in detail with reference to the accompanying drawings.

1 illustrates a structure of a planar giant multiple antenna system based on a heterogeneous network according to an exemplary embodiment of the present invention.

Since the planar giant multi-antenna system shown in FIG. 1 is based on a heterogeneous network, the small service area 19 by the at least one small base station 12 in the macro service area 10 by the macro base station 11 may be used. ) Is distributed. The macro base station 11 and the at least one small base station 12 are connected through a backhaul network. Here, the case where the macro base station 11 and the small base station 12 have different cell identification information (cell ID) corresponds to scenario 3 of CoMP (Coordinated Multiple Point Transmission and Reception) defined in LTE-Advanced. Otherwise, all base stations, ie, the macro base station 11 and the small base station 12 have the same cell identification information (cell ID), correspond to scenario 4 of CoMP defined in LTE-Advanced. The heterogeneous network considered in the proposed embodiment considers both scenario 3 and scenario 4 above.

개의 송신 안테나와 수직적 차원에서 배열된

개의 송신 안테나로 구성되어 총

개의 안테나 원소로 이루어진 안테나 구조를 고려하였다. 통상적으로 수평적 차원에서 배열된

개의 송신 안테나는 마크로 기지국(11)을 중심으로 한 회전 방향으로 위치하는 단말들을 위한 빔을 형성한다. 일 예로 참조번호 a, b, c 각각에 해당하는 안테나 그룹들의 배열이 수평적 차원에서의 배열에 해당한다.The macro base station 11 has an antenna structure by a two-dimensional planar array. For example, the macro base station 11 is arranged in a horizontal dimension

Transmission antennas arranged in a vertical dimension

Consists of two transmit antennas

An antenna structure consisting of two antenna elements is considered. Typically arranged in horizontal dimensions

Tx antennas form beams for terminals located in a rotational direction about the macro base station 11. As an example, an array of antenna groups corresponding to each of reference numbers a, b, and c corresponds to an array in a horizontal dimension.

개의 안테나 원소들에 의해 수평적 차원에서의

개 빔과, 수직적 차원에서의

개 빔들로 구성된 이차원 패턴 빔들을 형성한다.Therefore, the macro base station 11

In horizontal dimensions by two antenna elements

Dog beam, in the vertical dimension

Form two-dimensional pattern beams consisting of two beams.

개의 송신 안테나는 마크로 기지국(11)에서 근거리에서 원거리로 방향으로 위치하는 단말들을 위한 빔을 형성한다. 일 예로 참조번호 a, b, c 각각에 해당하는 안테나 그룹 내에서 안테나들의 배열이 수직적 차원에서의 배열에 해당한다.And arranged in the vertical dimension

Tx transmit antennas form beams for terminals located in a short-range to long-range direction at the macro base station 11. For example, the array of antennas in the antenna group corresponding to each of the reference numerals a, b, and c corresponds to the arrangement in the vertical dimension.

2D-DFT (discrete Fourier Transform) 프리코딩 매트릭스 (precoding matrix) U를 구성하는

크기의 칼럼 벡터로 신호를 프리코딩하여 전송한다. 상기 프리코딩 매트릭스 U를 구성하는 하나의 칼럼 벡터는 하나의 빔 성형 가중치에 해당한다. 상기 빔 성형 가중치를 이용하여 빔 성형 (또는 프리코딩)할 경우, 신호를 전송하기 위한 하나의 빔을 무선 채널에 형성할 수 있다.On the other hand, in the planar giant multi-antenna system, the macro base station 11

Constituting a 2D-DFT (discrete Fourier Transform) precoding matrix U

The signal is precoded with a column vector of size and transmitted. One column vector constituting the precoding matrix U corresponds to one beam shaping weight. When beam shaping (or precoding) using the beam shaping weights, one beam for transmitting a signal may be formed in a wireless channel.

Therefore, the weight vector and the beam have a one-to-one relationship, and when referring to the beam, the weight vector and the beam may have the same meaning as referring to the weight vector forming the beam.

개의

칼럼 벡터

은, 이차원 공간에서 수평적 차원에서

개의 직교하는 송신 빔들과 수직적 차원에서

개의 직교하는 송신 빔들로 구성된 총

개의 직교하는 송신 빔들을 형성한다. 따라서 마크로 기지국(11)의 평면 거대 다중 안테나 시스템에서 형성하는

개의 직교하는 송신 빔들은, 전체 셀 영역을 이차원적으로 수평적 차원에서

개와 수직적 차원에서

개의 영역들로 나눈 소형 영역을 각각 서비스 한다.Meanwhile U

doggy

Column vector

In horizontal dimension in two-dimensional space

In the vertical dimension with the orthogonal transmission beams

Total of four orthogonal transmit beams

Two orthogonal transmit beams. Therefore, formed in the planar large multi-antenna system of the macro base station 11

Orthogonal transmit beams, the entire cell area is two-dimensionally and horizontally

In a vertical dimension with the dog

Each small area divided into three areas is serviced.

Therefore, when the transmission beam that is responsible for the small area is not formed (that is, when the weight of the transmission beam is not used for signal transmission), the signal of the macro base station 11 is not transmitted to the small area. Through this operation, it is possible to form a shadow area in which a signal by the PDCCH or PDSCH of the macro base station 11 is not transmitted to the small cell area (that is, the small service area) of the small base station 12. Therefore, the terminals 17 and 18 receiving the service from the small base station 12 can avoid the interference by the macro base station 11.

개의 직교하는 송신 빔들(a, b, c), 즉 이차원 패턴 빔들을 형성하고, 각 송신 빔은 전체 마크로 서비스 영역(10)을 이차원적으로 형성된 수평적 차원에서의

개 분할과 수직적 차원에서의

개의 분할에 의해

개의 소형 영역으로 나누어 무선 통신 서비스를 제공한다.Referring to FIG. 1, the macro base station 11 provides a wireless communication service for the terminals 13, 14, 15, and 16 located in the macro service area 10 that do not overlap the small service area 19. . To this end, the macro base station 11

Two orthogonal transmit beams (a, b, c), i.e. two-dimensional pattern beams, each transmitting beam in a horizontal dimension formed two-dimensionally into the entire macro service area (10)

Dog segmentation and vertical dimension

By division

The wireless communication service is divided into three small areas.

The small base station 12 provides a wireless communication service for the target terminals 17 and 18 located in the small service area 19. The target terminals 17 and 18 may assume that data is transmitted by different beams selected from among N vertical beams arranged at the m th position in the horizontal dimension transmitted from the macro base station 11. That is, it may be assumed that data is transmitted by space division multiple access (SDMA) in the vertical dimension.

In contrast, the terminal 15 located in the macro service area 10 has a spatial division multiplexing by three beams selected from among N vertical beams arranged at the m ′ th position in the horizontal dimension transmitted from the macro base station 11. It can be assumed that data is transmitted by (spatial multiplexing, SM).

In addition, the terminals 16, 17, and 18 have high channel gains due to three vertical beams constituting a beam group corresponding to the reference number c at the same position in the horizontal dimension of the macro base station but at different positions in the vertical dimension. It is possible to receive a signal. However, since the target terminals 17 and 18 located in the small service area 19 must receive a wireless communication service from the small base station 12, the macro base station 11 affects the target terminals 17 and 18. In order to minimize interference, the beam that provides the maximum channel gain (ie, the maximum interference) to the target terminals 17 and 18 among the beams in the beam group corresponding to the reference c is not used. That is, the interference beam is formed as a zero power beam.

Accordingly, the target terminals 17 and 18 may calculate the CQI for the signal in which the inter-cell interference is suppressed by receiving the signal in which the inter-cell interference is suppressed received from the macro base station 11. The target terminals 17 and 18 may feed back the CQI calculated by the signal in which the inter-cell interference is suppressed to the small base station 12. As a result, the small base station 12 may reflect the effect of avoiding inter-cell interference when determining resource scheduling and MCS (Modulation and Coding Scheme) for the target terminals 17 and 18. This would be one reason for increasing the transmission capacity of the small base station 12.

Meanwhile, as described above, in order to perform the scheduling in which the macro base station 11 avoids the inter-cell interference, the targets located in the terminals 13 14, 15, 16, 17, 18, and 19, in particular, the small service area 19 are used. It is necessary to feed back information (eg, an interference beam index) about an interference beam acting as interference between internal cells from the terminals 17 and 18. The macro base station 11 collects the interference beam indexes fed back from the target terminals 17 and 18 to avoid inter-cell interference, and sets an interference beam index by a weight or zero power beam not to be used. Can be determined.

In addition, the macro base station 11 shares the determined interference beam index set with the target terminals 17 and 18 so that the target terminals 17 and 18 are transmitted by the macro base station 11. Using the information on the beam to estimate the CQI suppressed the main interference by the macro base station 11, and to feed back to the small base station 12.

2 illustrates a procedure of performing resource scheduling for a small service area in a planar giant multi-antenna system based on a heterogeneous network according to an embodiment of the present invention.

Referring to FIG. 2, the macro base station stores information (interference beam index, etc.) fed back by terminals located in the macro service area or target terminals located in at least one small service area superimposed on the macro service area. In step 200, a set of interference beam indices for each of the at least one small service area is determined.

For example, the macro base station combines the interference beam indexes reported from at least one target terminal located in each small service area to form an interference beam index set in the small service area. An interference beam index set configured for each small service area is provided to the target terminal located in the corresponding small service area by the macro base station. For example, the macro base station may provide the configured interference beam index set to the target terminal through a small base station connected by a backbone or directly to the target terminal through a PDCCH.

Meanwhile, the macro base station sets a column vector corresponding to the interference beam among the column vectors constituting the precoding matrix for beam shaping so that signal transmission by the interference beam constituting the interference beam index set can be blocked.

The target terminal ignores the signal received in the corresponding interference beam by using the interference beam index set provided from the macro base station in the received signal and measures the channel state for the downlink by the remaining signals (step 210). The target terminal reports the CQI corresponding to the measured channel state to the small base station. That is, the target terminal can measure the CQI avoiding the inter-cell interference by considering the interference beam index set when measuring the channel state for the downlink.

The small base station performs scheduling to allocate resources for the target terminal by using the CQI information reported from the target terminal located in the small service area where the small base station provides the wireless communication service (step 220).

3 illustrates an example of measuring channel quality of a small service area in a planar giant multi-antenna system based on a heterogeneous network according to an exemplary embodiment of the present invention. In FIG. 3, two small base stations 32 and 34, a macro base station 33 (hereinafter referred to as a 'source macro base station') connected by the two small base stations 32 and 34 and a backbone network, and the source macro It is assumed that one neighboring macro base station (Outside of CoMP cell) 35 adjacent to the base station 33 is. In this case, it is assumed that the signal transmitted by the neighboring macro base station 35 may interfere with the target terminal 31 located in the small service area by the small base station 32. That is, it is assumed that the two small base stations 32 and 34 and the macro base station 33 form one CoMP connected to the backbone, and the neighboring macro base station 35 does not belong to the CoMP.

Referring to FIG. 3, the target terminal 31 is connected to the small base station 32 by the power of the received signal 36 and the same cell interference, inter-cell interference 38, and inter-cell interference 37. Estimate the channel quality for As an example, the estimated channel quality for the downlink may be a signal-to-noise and interference ratio (SINR).

In particular, the target terminal 31 can estimate the CQI avoiding the inter-cell interference in CoMP by estimating the same cell interference based on the interference beam index set provided from the macro base station 33.

4 illustrates a signal processing procedure for performing resource scheduling for a small service area in a planar giant multi-antenna system based on a heterogeneous network according to an embodiment of the present invention. In FIG. 4, it is assumed that two target terminals exist in one small service area existing in one macro service area. However, the operation according to the proposed technical feature is not limited to the assumed environment. That is, it will be apparent that a plurality of small base stations exist in one macro service area or each small base station can be commonly applied to all situations in which one or more target terminals are located.

In addition, there may be another macro service area adjacent to the macro service area. In this case, a signal in another adjacent macro service area may act as interference with the small service area.

Referring to FIG. 4, target terminals 1 and 2 (17, 18) receive signals transmitted by the macro base station 11 through two-dimensional pattern beams, and determine at least one interference beam index based on the received signals. do. The target terminals 1 and 2 (17, 18) configure the feedback information based on the determined at least one interference beam index, and report the configured feedback information to the macro base station 11 (steps 410 and 412). ).

As an example, a control flow performed by the target terminal to configure the feedback information and report it to the macro base station is illustrated in FIG. 5. In FIG. 5, the macro base station and the small base stations in a heterogeneous network consider transmitting channel state identifiers (CSI-RSs) orthogonal to each other. This is to allow the target terminal to separately estimate the downlink channel states of the macro base station and the small base station.

Referring to FIG. 5, the target terminal determines a serving eNB to which it will communicate (step 510). For example, the target terminal may estimate a downlink channel state of each base station based on orthogonal CSI-RSs of the macro base station 11 and the small base station 12, and determine a serving base station based on the estimation result. For example, the target terminal will determine, as the serving base station, the base station which is considered to have the best channel condition when considering the downlink channel state of each base station estimated by the CSI-RS.

The target terminal determines whether the previously determined serving base station is a small base station (step 512). That is, the target terminal determines whether it is currently located in the small service area. For example, since the target terminal can identify the corresponding base station by the CSI-RS, it can determine whether the small base station is selected as the serving base station by the CSI-RS considered for the determination of the serving base station.

If it is determined that it is located in the macro service area rather than the small service area, the target terminal will perform an operation according to resource scheduling defined by the general procedure required by the macro base station.

However, when determined to be located in the small service area, the target terminal will perform the following operation for measuring the CQI in the small service area by avoiding interference due to a signal transmitted from the macro base station.

)를 추정한다 (514단계).More specifically, when the small base station is determined as the serving base station, the target terminal includes a channel coefficient corresponding to each of the two-dimensional beams formed by the macro base station.

(Step 514).

개의 송신 안테나와 자신의 수신 안테나 간에 형성되는

개의 하향 링크들에 대한 채널 벡터

를 추정한다. For example, the target terminal estimates a downlink channel with the macro base station using the CSI-RS received from the macro base station. When the macro base station transmits the CSI-RS orthogonal to each of the two-dimensional pattern beams (transmission antennas), the target terminal uses the CSI-RS estimation of the macro base station.

Formed between the Tx antennas and its own Rx antennas

Vector for two downlinks

Estimate

를 이용하여 프리코딩 벡터

에 의해 형성된, 이차원 빔 공간에서 수평적 차원에서

번째와 수직적 차원에서

번째에 위치하는 빔에 의해 수신 가능한 하향링크 채널 응답

을 하기 <수학식 1>에 의해 구할 수 있다.The target terminal estimates the channel vector

Precoding vector using

Formed in the two-dimensional beam space in the horizontal dimension

In the second and vertical dimensions

Downlink channel response receivable by the first located beam

It can be obtained by <Equation 1>.

Equation 1

In Equation 1, it is assumed that the target terminal uses one receiving antenna.

2D-DFT 프리코딩 매트릭스 U의

크기의 칼럼 벡터들로 각각 프리코딩, 즉 빔 성형하여 CSI-RS를 송신할 경우, 대상 단말은 CSI-RS 추정을 통해,

개 송신 빔에서 UE의 수신 안테나로의

하향링크 채널 벡터

를 직접 추정할 수 있다.Also, at the macro base station

Of 2D-DFT precoding matrix U

When transmitting the CSI-RS by precoding, i.e., beam shaping each of the column vectors having a size, the target terminal uses the CSI-RS estimation to

Dog beams to the receive antennas of the UE

Downlink channel vector

Can be estimated directly.

에 대한 추정이 완료되면, 상기 추정이 완료된 하향링크 채널 벡터

에 의해 최대 함수 값을 갖는 빔 인덱스를 결정한다 (516단계). 예컨대 상기 대상 단말은

개의 채널 계수

를 입력으로 하는 임의의 함수 f(.)의 결과 값들을 비교하고, 상기 비교에 의해 최대 결과 값을 갖는 빔의 이차원 인덱스 (

)를 선택한다. 즉, 함수 f(.)의 결과 값을 최대로 하는 수평 빔의 인덱스

과 수직 빔의 인덱스

을 구한다.The target terminal is a downlink channel vector

When the estimation is completed, the downlink channel vector of which the estimation is completed

In step 516, the beam index having the maximum function value is determined. For example, the target terminal

Channel coefficients

Compare the result values of any function f (.) That takes as input, and the two-dimensional index of the beam having the

Select). That is, the index of the horizontal beam that maximizes the result of the function f (.)

And the index of the vertical beam

Obtain

An example is defined in Equation 2 below.

Equation 2

의 크기인

또는 채널 계수

에 의해 전송 가능한 데이터 율, 그리고

에 의해 수신 가능한 신호 대 잡음 및 간섭 비 (SINR: Signal-to-Interference and Noise Ratio) 등과 같은 함수로 정의할 수 있다.Where the arbitrary function f (.) Is the channel coefficient

Is the size of

Or channel count

Data rate that can be transmitted by, and

It can be defined as a function such as a signal-to-interference and noise ratio (SINR) that can be received by.

)와, 앞에서 결정한 최대 결과 값을 갖는 빔의 이차원 인덱스 (

) (이하 ‘최대 결과 빔 인덱스’라 칭한다)를 사용하여 소정 조건을 만족하는 간섭 빔 인덱스를 검출한다 (518단계).The target terminal is a channel coefficient estimated for each two-dimensional pattern beam (

) And the two-dimensional index of the beam with the maximum

(Hereinafter, referred to as 'maximum result beam index') to detect an interference beam index satisfying a predetermined condition (step 518).

For example, the target terminal sequentially selects two-dimensional pattern beams and substitutes the channel coefficients estimated for the selected beams into a predefined function f (.) (Hereinafter, referred to as an 'presumed function result value'). ) Satisfies the preset threshold, it is determined that the selected beam is an interference beam.

)의 빔에 대해 추정한 채널 계수 (

) (이하 ‘최대 결과 빔 채널 계수’라 칭한다)의 소정 배수 (

)에 의해 결정될 수 있다. 즉 순차적으로 선택된 빔의 추정 함수 결과 값 (

)이 최대 결과 빔 채널 계수를 사전에 정의된 함수 f(.)에 대입하였을 때의 결과 값 (이하 ‘최대 추정 함수 결과 값’이라 칭한다) (

)의

배 이상인 빔의 인덱스를 i번째 스몰 기지국에 속하는 k번째 UE에게 높은 간섭을 주는 마크로 기지국의 셀간 간섭 빔 인덱스 집합

을 포함시킨다.For example, the preset threshold may be a maximum result beam index (

Estimated channel coefficient for the beam of

) A predetermined multiple of (hereinafter referred to as the 'maximum result beam channel coefficient')

Can be determined by That is, the result of the estimation function of the sequentially selected beams (

) Is the result of substituting the maximum result beam channel coefficient into a predefined function f (.) (Hereinafter referred to as 'maximum estimated function result value') (

)of

A set of inter-cell interference beam indices of a macro base station which gives a higher interference to a k- th UE belonging to an i- th small base station with an index of a beam that is more than twice.

Includes.

에 포함시킬 빔의 인덱스를 선별하기 위한 일 예를 정의하고 있다.Equation 3 is a set of inter-cell interference beam indexes of a macro base station.

An example for selecting the index of the beam to be included in the definition is defined.

Equation 3

개의 이차원 패턴 빔들에 대해서 모두 수행한다. As defined by Equation 3 above,

All of the two two-dimensional pattern beams are performed.

을 결정하는데 필요한 파라미터인

는 모든 대상 단말들에게 공통적인 값 또는 대상 단말 별로 서로 다른 값으로 정의할 수 있다. 그리고 파라미터인

는 기지국과 대상 단말들이 공유하기 위해, 미리 표준 규격을 통해서 약속하거나, 기지국이 하향 링크 무선 자원 제어 (RRC: Radio Resource Control) 시그널링을 통해 모든 대상 단말들에게 전달할 수도 있다.Meanwhile, the inter-cell interference beam index set

Parameter to determine the

May be defined as a value common to all target terminals or a different value for each target terminal. And the parameter

In order to share between the base station and the target terminals, the base station may make an appointment in advance through a standard standard, or the base station may deliver it to all target terminals through downlink radio resource control (RRC) signaling.

When the detection of the at least one interference beam index is completed, the target terminal configures feedback information including the detected interference beam index, and provides the configured feedback information to the macro base station (step 520).

를, i번째 스몰 기지국을 경유하여, 마크로 기지국으로 피드백 한다.For example, the target terminal sets an interference beam index of the macro base station that gives high inter-cell interference to itself (the k- th terminal belonging to the i- th small base station).

Is fed back to the macro base station via the i- th small base station.

By receiving the feedback information from each of the target terminals 17 and 18 by the above-described operation, the macro base station 11 determines the interference beam index set by the sum of the interference beam indices included in the received feedback information. . In this case, the macro base station 11 may configure an interference beam index set for each target terminal, for each small base station 12, or for all terminals located in a macro service area. Accordingly, the macro base station 11 may apply the range of the target feedback information for which the sum set is to be obtained, depending on a scheme for configuring the interference beam index set.

를 이용하여, i번째 스몰 서비스 영역에 높은 간섭을 주는 간섭 빔 인덱스 집합

를 결정한다.For example, the macro base station 11 may configure an interference beam index set for each target terminal. In other words, the macro base station 11 is a set of inter-cell interference beam indexes that give high interference to the k- th terminal belonging to the i- th small base station fed back from the target terminals 17 and 18.

A set of interference beam indices that give high interference to the i th small service area using

Determine.

의 합 집합에 의해 i번째 스몰 기지국에 대한 간섭 빔 인덱스 집합 (

)을 결정하는 예를 보이고 있다.Equation 4 is a set of interference beam indexes reported by each of the K target terminals belonging to the i th small base station.

A set of interference beam indexes for the i th small base station by the sum set of

Shows an example of determining).

Equation 4

)은 마크로 기지국(11)에 의해 i번째 스몰 기지국(12)을 경유하여 상기 i번째 스몰 기지국을 서빙 기지국으로 하는 대상 단말들(17, 18)에게 전달되거나 마크로 기지국(11)에 의해 i번째 스몰 기지국(12)을 서빙 기지국으로 하는 대상 단말들(17, 18)에서 직접 전달될 수도 있다 (416단계, 418단계).Set of interference beam indices determined by

) Is by way of the i-th small base station 12 by the macro base station 11 the destination of the i-th small base station to the serving base station (17, 18) to pass or the i-th small by the macro base station 11 The target terminals 17 and 18 using the base station 12 as the serving base station may be directly transmitted (steps 416 and 418).

를 이용하여, 각 스몰 서비스 영역에서 높은 간섭을 주는 간섭 빔 인덱스 집합

의 합 집합에 의한 전체 간섭 빔 인덱스 집합

를 결정한다.As another example, the macro base station 11 may configure an interference beam index set for each small base station. That is, the macro base station 11 is a set of inter-cell interference beam indexes fed back from all target terminals.

A set of interference beam indices that give high interference in each small service area using

Set of total interference beam indices by sum of

Determine.

를 이용하여, 전체 스몰 서비스 영역 (I개)에서 높은 셀간 간섭을 주는 간섭 빔 인덱스 집합

를 결정한다.In other words, the macro base station 11 is a set of inter-cell interference beam indexes that give high inter-cell interference in the i- th small service area.

A set of interference beam indices that give high inter-cell interference in the entire small service area (I) using

Determine.

의 합 집합을 결정하고, 상기 결정된 모든 스몰 서비스 영역에서의 합 집합들의 합 집합에 의해 전체 간섭 빔 인덱스 집합

를 구성한다.For example, the interference beam index set of the i th small base station

Determine a set of sums, and set the total interference beam index by the sum set of sum sets in all the determined small service areas.

Configure

의 합 집합에 의해 전체 마크로 서비스 영역에 대한 간섭 빔 인덱스 집합 (

)을 결정하는 예를 보이고 있다.Equation 5 below is a set of interference beam indexes reported by target terminals each serving I small base stations located in a macro service area as serving base stations.

Set of interference beam indices for the entire macro service area by the sum set of

Shows an example of determining).

Equation 5

)은 마크로 기지국(11)에 의해 i번째 스몰 기지국(12)을 경유하여 상기 i번째 스몰 기지국을 서빙 기지국으로 하는 대상 단말들(17, 18)에게 전달되거나 마크로 기지국(11)에 의해 마크로 서비스 영역에 위치하는 모든 단말들에서 직접 전달될 수도 있다 (416단계, 418단계).Set of interference beam indices determined by

) Is a macro coverage area by the i-th small via the base station 12, the i delivered to the destination terminal (17, 18) for the second small base station to the serving base station or the macro base station 11 by the macro base station 11 It may be delivered directly from all the terminals located in (step 416, step 418).

이 변경될 시에 비주기적으로 수행될 수도 있다.By the above-described steps 410 to 418, the macro base station determines the interference beam index set, and sharing the same with the terminals is performed periodically every TTI, or the interference beam index set of the terminals

It may be performed aperiodically when this is changed.

을 수신한 대상 단말(17, 18) 각각은 상기 수신한 간섭 빔 인덱스 집합

을 고려하여 상기 마크로 기지국(11)에 의한 간섭을 억제하여 서빙 기지국, 즉 스몰 기지국(12)으로부터의 하향 링크에 대한 채널 품질을 추정한다 (420단계, 422단계).Set of interference beam indices as described above

Each of the target terminals (17, 18) receiving the received interference beam index set

In consideration of this, the interference by the macro base station 11 is suppressed to estimate the channel quality of the downlink from the serving base station, that is, the small base station 12 (steps 420 and 422).

2D-DFT 프리코딩 매트릭스 U의

크기의 칼럼 벡터들로 각각 프리코딩, 즉 빔 성형하여 PDCCH와 PDSCH를 전송하는 것을 고려한다.For example, the macro base station 11

Of 2D-DFT precoding matrix U

Consider transmitting the PDCCH and the PDSCH by precoding, i.e., beamforming, each of the column vectors of size.

에 속하는 빔들을 사용하지 않음으로써, 스몰 기지국에 속하는 대상 단말들에게 주는 셀간 간섭을 회피하게 된다. 이러한 간섭 회피 동작으로 인해, 대상 단말들이 겪는 셀간 간섭 량이 감소하게 되어 수신 SINR이 증가하게 될 것이다.At this time, the macro base station 11 sets an index of interfering beams for inter-cell interference in all small service areas.

By not using the beams belonging to, it avoids the inter-cell interference given to the target terminals belonging to the small base station. Due to this interference avoidance operation, the amount of inter-cell interference experienced by the target terminals will be reduced, thereby increasing the received SINR.

In order to connect the increase of the received SINR of the target terminal to the increase in the system transmission capacity, the inter-cell interference of the target terminal is avoided when the scheduling for determining the target terminal to transmit data and the MCS of the data string to transmit to the scheduled target terminal are determined. It should be performed based on the received SINR.

To this end, each target terminal calculates the CQI for the case where the inter-cell interference received from the macro base station is avoided and feeds it back, so that the macro base station performs scheduling and MCS determination based on this.

For example, FIG. 6 illustrates a control flow performed by a target terminal for measuring a channel quality of a downlink with a small base station and reporting the same to the small base station.

Referring to FIG. 6, the target terminal is provided with an interference beam index set by the macro base station. As described above, the interference beam index set may be directly provided by the macro base station or through a small base station serving as the serving base station of the target terminal (step 610).

)을 추정한다 (612단계). 일 예로 상기 대상 단말은 서빙 기지국으로부터 수신되는 신호만을 이용하여 수신 신호 전력 (

)을 추정할 수 있다.The target terminal is the power (for the received signal)

(Step 612). For example, the target terminal uses only the signal received from the serving base station to receive the received signal power (

) Can be estimated.

를 추정한다.For example, the target terminal estimates a downlink channel with the serving base station through the CSI-RS received from the serving base station, and selects a precoding matrix index (PMI) and rank selected by the target downlink channel. Received signal power by multiplying the precoding vector indicated by the identifier (RI: Rank Indicator)

Estimate

를 추정한다 (614단계). 예컨대 상기 동일 셀 간섭

는 서빙 기지국에서 공간 다중화 (SM: Spatial Multiplexing)나 SDMA에 의해 동시에 전송되는 다른 데이터 열로부터 발생한다.The target terminal is the interference in the small service area, that is, the same cell interference due to the signal transmitted by the serving base station

Estimate (step 614). For example the same cell interference

Occurs from spatial multiplexing (SM) or other data streams transmitted simultaneously by SDMA at the serving base station.

를 추정할 수 있다.As an example, the target terminal multiplies the weight vector used for transmission of the data sequence that interferes with the estimated downlink channel for the serving base station, thereby interfering with the same cell.

Can be estimated.

를 추정한다 (616단계). 예컨대 LTE-A Rel-11에서는, 셀간 간섭을 정확히 측정하기 위해, IMR (Interference Measurement Resource)을 정의하였다. 상기 IMR은 제로 전력 CSI-RS를 전송하는 RE들의 집합, 즉 CSI-RS 전송을 위해 할당된 RE들 중에서 CSI-RS를 전송하지 않는 RE의 집합을 의미한다. 따라서 CoMP에 속하는 마크로 기지국과 스몰 기지국은 동일한 IMR에서 CSI-RS를 전송하지 않고, 해당 IMR에서 수신 되는 신호의 크기를 측정함으로써, CoMP 속하지 않는 기지국들로부터 수신되는 간섭 량, 즉

를 측정할 수 있다.The target terminal is an interference between outer cells received from a neighboring base station located outside the base station belonging to the same CoMP

Estimate (step 616). For example, in LTE-A Rel-11, IMR (Interference Measurement Resource) has been defined to accurately measure inter-cell interference. The IMR refers to a set of REs that transmit zero power CSI-RS, that is, a set of REs that do not transmit the CSI-RS among the REs allocated for CSI-RS transmission. Therefore, the macro base station and the small base station belonging to CoMP do not transmit the CSI-RS in the same IMR, and measure the magnitude of the signal received in the corresponding IMR, so that the amount of interference received from the base stations not belonging to the CoMP, that is,

Can be measured.

를 추정한다 (618단계). 이때 대상 단말은 내부 셀간 간섭 회피 기법에 의해 내부 셀간 간섭이 억제된

를 정확히 추정할 수 있어야 한다. 이를 위해 상기 대상 단말은 CoMP 내부의 마크로 기지국에 의해 제공된 간섭 빔 인덱스 집합을 이용한다.The target terminal is inter-cell interference due to the signal received from the macro base station in the CoMP

Estimate (step 618). At this time, the target terminal is suppressed the interference between the internal cells by the inter-cell interference avoidance technique

We need to be able to estimate To this end, the target terminal uses an interference beam index set provided by a macro base station in CoMP.

For example, the target terminal estimates a downlink channel with the macro base station through a CSI-RS received from a macro base station in CoMP, multiplies the estimated downlink channel by a weight vector used by the macro base station, and transmits the corresponding beam. It is possible to estimate the interference power by.

개의 송신 빔 중에서 간섭 빔 인덱스 집합

에 속하는 빔들을 사용하지 않는다는 가정하에, 대상 단말은 하기 <수학식 7>과 같이

를 계산한다.Therefore, the internal macro base station is full

Of interfering beam indices of four transmit beams

Under the assumption that the beams belonging to are not used, the target terminal is expressed by Equation 7 below.

Calculate

Equation 6

은 내부 마크로 기지국의 (m,n) 번째 빔에 의해 대상 단말이 수신하는 간섭 전력을 의미하며, 는

집합 원소들의 평균을 의미한다.here,

Denotes interference power received by the target terminal by the ( m, n ) th beam of the internal macro base station, Is

Mean the average of the set elements.

에 속하지 않는 (m,n) 번째 빔에 의한 간섭 전력의 평균에 의해

를 계산한다.Thus the set of interference beam indices

By the average of the interference power by the ( m, n ) th beam that does not belong to

Calculate

, 동일 셀 간섭

, 외부 셀간 간섭

및 내부 셀간 간섭

을 사용하여 서빙 기지국과의 하향 링크에 대한 채널 품질을 계산한다 (620단계). 즉 상기 대상 단말은 내부 마크로 기지국에 의한 간섭을 회피하여 서빙 기지국으로부터 수신되는 신호에 대한 CQI를 계산한다.The target terminal is the received signal power calculated and estimated in the above-described step

Same cell interference

Inter-cell interference

And inter-cell interference

Compute the channel quality for the downlink with the serving base station using the step (620). That is, the target terminal calculates the CQI for the signal received from the serving base station by avoiding interference by the internal macro base station.

를 계산하는 일 예를 보이고 있다.Equation 7 below represents SINR representing channel quality with a serving base station.

It shows an example of calculating the.

Equation 7

은 대상 단말에 의해 수신된 잡음의 정도를 나타낸다.here

Denotes the degree of noise received by the target terminal.

The target terminal reports the calculated channel quality information to the serving base station (step 622). In response to this, in FIG. 4, each target terminal 17 or 18 reports its estimated CQI to the small base station 12 (steps 424 and 426).

In operation 428, the small base station 12 that receives the CQI from each of the target terminals 17 and 18 by the above operation performs a scheduling operation for resource allocation based on the received CQI.

에 속하는 빔들은, 스케줄링 시에 할당되지 않도록 함으로서, PDCCH와 PDSCH을 전송할 시에 사용되지 않도록 한다.For example, the small base station performs scheduling on the target terminals 17 and 18 serving as the serving base station based on the CQI in which the inter-cell interferences to which the target terminals 17 and 18 are fed back are avoided. As a result, the small base station 12 may transmit the PDCCH and the PDSCH to the target terminals 17 and 18 with the MCS suitable for the corresponding CQI. Only a set of interference beam indices determined by the macro base station 11

The beams belonging to are not allocated at the time of scheduling, so they are not used when transmitting the PDCCH and PDSCH.

에 속하는 빔들이 담당하는 영역에는 마크로 기지국의 신호가 전송되지 않기 때문에, 해당 영역의 스몰 기지국에 속하는 대상 단말들이 겪는 CoMP 내부 셀간 간섭이 충분히 회피될 수 있다.therefore

Since the signal of the macro base station is not transmitted in the area that the beams belong to, the interference between the CoMP internal cells experienced by the target terminals belonging to the small base station of the corresponding area can be sufficiently avoided.

In addition, the proposed technique for estimating CMPI from which CoMP internal inter-cell interference is avoided excludes a set of interference weight vectors that the UE should consider when estimating inter-cell interference, and excludes weight vectors that will not be used by the interference avoidance technique performed at the macro base station. To limit it. In addition, the proposed CQI estimation technique can increase the transmission capacity of CoMP by accurately reflecting the reduction of the inter-cell interference caused by CoMP internal interference avoidance techniques in the CQI estimation.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but those skilled in the art may be embodied by various modifications without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the appended claims, but also by the equivalents of the claims. In addition, these modifications should not be individually understood from the technical spirit or prospect of the present invention.

Claims (15)

The macro service area in a heterogeneous network in which a macro service area is formed by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension, and at least one small service area is formed in the macro service area. A method for shaping the M * N beams by a base station supporting signal transmission / reception in sigma, with respect to a transmission signal in the at least one small service area among signals to be transmitted by the M * N beams Selecting at least one interference prediction beam configured to transmit a signal capable of interference, and intercell interference in the at least one small service area due to a signal to be transmitted by the at least one interference prediction beam selected Considering beam shaping for each of the M * N beams. The method of claim 1, wherein the selecting comprises: receiving feed-back information from terminals located in the macro service area, and selecting the at least one interference prediction beam based on the received feedback information. Beam forming method comprising the step of. The terminal of claim 2, wherein the feedback information transmitted by the terminal located in the small service area among the terminals located in the macro service area is located in the at least one small service area among the M * N beams. And an interference beam index indicating a beam interfering with the inter-cell, wherein the inter-cell interfering beam is a beam which gives the largest inter-cell interference to a terminal located in the at least one small service area or the at least one small The beam shaping method characterized in that the beam to give the inter-cell interference above a predetermined threshold to the terminal located in the service area. The method of claim 3, wherein an interference beam index set is configured for each small service area by using interference beam indexes received from all terminals located in the at least one small service area, and the interference beam index set is configured as the corresponding small service. The method further comprises: transmitting to the UE located in the region for each TTI, and transmitting the changed interference beam index set to the UE located in the corresponding small service area when the interference beam index set provided for each TTI is changed. Forming method. The M * N beams according to claim 1, wherein the beamforming is performed by considering inter-cell interference in the at least one small service area due to a signal to be transmitted by the at least one selected beam. Determining a beam shaping weight for each of the beamforming methods; and constructing a precoding matrix for beam shaping using the beam shaping weights determined for each of the M * N beams as a column vector. The M * N in a heterogeneous network that forms a macro service area by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension, and forms at least one small service area in the macro service area. A base station supporting signal transmission / reception in the macro service area for shaping two beams, the base station supporting a feed-back information from terminals located in the macro service area, and a feed back received by the receiver Select at least one interference prediction beam configured to transmit a signal that may interfere with a transmission signal in the at least one small service area among the signals to be transmitted by the M * N beams using information, The at least one small due to the signal to be transmitted by the at least one interfering predicted beam A control unit performing beam shaping for each of the M * N beams in consideration of inter-cell interference in a vis region, and transmitting a signal by the M * N beams based on the beam shaping performed by the control unit A base station including a transmitter. The method of claim 6, wherein the feedback information transmitted by a terminal located in the at least one small service area among the terminals located in the macro service area and received by the receiving unit is the at least one of the M * N beams. And an interference beam index indicating a beam interfering with inter-cell interference in a terminal located in one small service area, wherein the inter-cell interfering beam has the largest inter-cell interference for a terminal located in the at least one small service area. The base station, characterized in that the beam to give the inter-cell interference more than a predetermined threshold to the terminal located in the at least one small service area. The method of claim 7, wherein the controller configures an interference beam index set for each small service area by using an interference beam index received from all terminals located in the at least one small service area, and configures the configured interference beam index. Control the transmitter to transmit the Tx to the UE located in the corresponding small service area and transmit the changed interference beam index set to the UE located in the small service area when the interference beam index set is changed. Base station characterized in that. According to claim 6, The control unit, Beam shaping for each of the M * N beams in consideration of inter-cell interference in the at least one small service area due to the signal to be transmitted by the at least one selected beam And determine a weight and configure a precoding matrix for beam shaping, wherein the beam shaping weights determined for each of the M * N beams are column vectors. In a heterogeneous network in which a macro service area is formed by M * N beams by a two-dimensional antenna array considering horizontal and vertical dimensions simultaneously, and at least one small service area is formed in the macro service area. a method for location UE reports the channel quality information, the power of the signals received from the small base station to service the small service area (S), the same-cell interference (I_ _intra), external cell interference (I_ _{inter, NoCoMP)} and the inner inter-cell interference (I_ _{inter, CoMP)} an estimation procedure, and the estimated received signal power (S), the same-cell interference (I_ _intra), external cell interference (I_ _{inter, NoCoMP)} and the inner inter-cell interference (I_ _{inter comprising} the step of transmitting to the process and the small base station to configure the channel quality information that _CoMP) configured to channel quality information using, in which the inner Interference (I_ _{inter, CoMP)} liver, characterized in that the estimated by the average of the interference power due to the beams that are not part of the interference beam index set provided by the macro base station serving the macro coverage area of the M * N of beams How to report channel quality information. The channel of claim 10, further comprising: providing to the macro base station an interference beam index indicating at least one beam that gives the largest inter-cell interference among the M * N beams or the inter-cell interference above a predetermined threshold. How to report quality information. The method of claim 11, wherein the interference beam index set is provided by the macro base station every TTI or every change. The small service area in a heterogeneous network in which a macro service area is formed by M * N beams by a two-dimensional antenna array considering a horizontal dimension and a vertical dimension, and at least one small service area is formed in the macro service area. according to a terminal located in the small coverage area for reporting channel quality information to the small base station to service, power (S), the same-cell interference (I_ _intra) of a signal received from a base station to service the small service area, outside inter-cell interference (I_ _{inter, NoCoMP)} and the inner inter-cell interference (I_ _{inter, CoMP)} the estimated and the estimated received signal power (S), the same-cell interference (I_ _intra), external cell interference (I_ _{inter, NoCoMP)} and internal inter-cell interference _{(inter I_, CoMP)} and a control unit for configuring the channel quality information to use, configure the channel quality information under the control of the control unit The small and a transmitter for transmitting to the base station, wherein the internal inter-cell interference (I_ _{inter, CoMP)} has beams that are not part of the interference beam index set provided by the micro base station serving the macro coverage area of the M * N of beams It is estimated by the average of the interference power by the terminal. The transmitter of claim 13, wherein the controller is further configured to provide the macro base station with an interference beam index indicating at least one beam that provides the largest inter-cell interference among the M * N beams or the inter-cell interference above a predetermined threshold. Terminal characterized in that for controlling. The terminal of claim 14, wherein the interference beam index set is provided by the macro base station every TTI or every change.

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